KR101030303B1 - Method of Testing Array Type Light Source using Image Sensor - Google Patents

Abstract

Disclosed are a light source characteristic evaluation apparatus and method capable of accurately measuring individual optical characteristics of an arrayed light source. The disclosed light source characteristic evaluation device includes a light source including a plurality of micro apertures, an image sensor disposed under the light source, and having a plurality of pixels for receiving and imaging light emitted from the light source, and the light source and the An optical system interposed between the image sensors and forming light irradiated from the light source onto pixels of the image sensor, wherein a part of the pixels of the image sensor receive the light irradiated from the light source and image it; It is configured to evaluate the characteristics of the light source through the intensity and shape of. Accordingly, it is possible to improve the accuracy of light source characteristic measurement by securing the characteristics such as sensitivity, noise characteristics and defects for each pixel of the image sensor in advance and using the light source characteristics for evaluation.

Array light source, nano, aperture, evaluation, image sensor

Description

Apparatus and method for evaluating the characteristics of an array light source using an image sensor {Method of Testing Array Type Light Source using Image Sensor}

The present invention relates to an apparatus and method for evaluating light source characteristics, and more particularly, to an apparatus and method for evaluating characteristics of array light sources using an image sensor.

At present, in order to fabricate highly integrated semiconductor circuit elements and display elements, it is required to produce fine patterns below the diffraction limit of the light source. In order to produce such a fine pattern, research on a maskless exposure technique using an array light source instead of using a mask instead of forming a mask on an image recording surface has been actively conducted. The maskless exposure machine uses an array light source to generate an exposure pattern, and for the management of the exposure process, accurate evaluation of the characteristics of the array light source is required.

Also, in order to apply to a maskless exposure apparatus for a high resolution semiconductor manufacturing process, an array light source device having a high resolution by a near field effect has recently been proposed by the inventor of the present invention. ["2D light modulation micro aperture array device and using the same High speed fine pattern recording system (Korean Patent Publication No. 10-2005-0001086), and "Low-noise two-dimensional light modulation array device and high speed fine pattern recording system using the same (Korea Patent Publication No. 10-2005-0063857)"]

In order to secure the pattern uniformity formed by the two-dimensional array type light source, it is necessary to accurately measure the uniformity of light.

However, no separate equipment for evaluating the uniformity of the arrayed light source itself is currently provided, and the uniformity of the light source is evaluated using an image image detection element such as a general digital camera.

However, when the characteristics of each pixel of the array light source are measured using the image element, the evaluation result is absolutely affected by the characteristics of the image element.

In general, each pixel of the image sensor is known to show a significant difference in operating characteristics due to sensitivity and noise characteristics, and without considering such image sensor characteristics, it is impossible to accurately measure (evaluate) the pixel characteristics of the array light source. Do. For example, if the characteristics of the image device is poor, a problem that can be determined to be defective even though the light source is normal can easily occur.

Accordingly, it is an object of the present invention to provide an apparatus and method for evaluating light source characteristics capable of accurately measuring optical characteristics of individual array light sources.

The light source characteristic evaluation apparatus of the present invention for achieving the above object of the present invention comprises a light source including a plurality of micro-openings, a plurality of pixels disposed under the light source to receive and image the light irradiated from the light source And an optical system interposed between the light source and the image sensor to form light irradiated from the light source onto pixels of the image sensor, wherein a part of the pixels of the image sensor are light irradiated from the light source. And image it, and evaluate the characteristics of the light source through the intensity and shape of the image.

In addition, the method for evaluating the characteristics of a light source according to another embodiment of the present invention includes providing an optical characteristic evaluation apparatus including an optical system and an image sensor having a plurality of pixels. Arranging, and receiving light irradiated from the light source, and evaluating characteristics of the light source by an image detected by the image sensor.

In this case, prior to the step of evaluating the characteristics of the light source, evaluating the characteristics of the image sensor, the optical characteristic evaluation apparatus itself further comprises the step of detecting a defective pixel.

According to the present invention, the optical characteristics of the array light source are measured using a device composed of an optical system and an image sensor. At this time, before performing the light source evaluation, by measuring the characteristics of each pixel of the image sensor first to correct the measured value of the evaluation apparatus, it is possible to increase the measurement accuracy of the evaluation apparatus.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 1, the light source evaluation system 100 may include an optical system 120 and an image sensor 150.

An array light source 200 to be evaluated is disposed above the optical system 120.

In addition, the optical system 120 may be configured as a lens for projecting the light irradiated through the micro-opening of the array light source 200 to the image sensor 150 to form an image.

Here, the array light source 200 may include a plurality of array openings 210 arranged in a matrix form, as shown in FIG. 2. More specifically, the array light source 200 is formed on a lamp (not shown), a transparent substrate (not shown), and an array opening 210 of nanometer (or micrometer) diameter at regular intervals and formed at a bottom of the transparent substrate. ) May be formed of a metal thin film 220. Here, the lamp may be a laser light source generally used in a photolithography process.

In the present specification, the light incident from the array opening 210 to generate an array light source and the entire metal thin film 220 including the array opening 210 will be referred to as the light source 200. Denotes the uniformity of the light passing through the array opening 210, and the unit light source may refer to the light passing through the array opening 210. In addition, reference numeral 250 of FIG. 2 denotes a unit light source region, and indicates a region affected by the single opening 210.

In the present embodiment, a light source having an array opening 210 has been described as an example, but is not limited thereto. A light emitting diode (LED) or a vertical cavity surface emitting laser (VCSEL) having an array shape is not limited thereto. Of course, a laser) can be used.

The image sensor 150 is disposed below the optical system 120 and measures an image of a light source formed by the optical system 120. The image sensor 150 may be configured of a plurality of pixel arrays. As the image sensor 150, a CMOS image sensor or a solid-state imaging device may be used.

As illustrated in FIG. 3, the image sensor 150 includes a plurality of image sensor pixel groups 170 grouped into several pixels, and the one image sensor group 170 is one In response to the array opening 210, that is, the unit light source, light received and captured by the unit array light source 210 is received.

The operation of the array light source evaluation device having such a configuration will be described.

When light is irradiated from the unit array light source 210, the optical system 120 projects the light such that the light is formed on the image sensor pixel group 170 of the image sensor 150.

Then, the image sensor pixel group 170 of the image sensor 150 receives light emitted from the unit array opening 210 in response to the unit array light source 210, and corresponds to the image 160. Is output as shown in FIG. 3.

When normal light is irradiated from the unit array opening 210, the image sensor pixel group 170 outputs an image having a predetermined shape in uniform intensity corresponding to the light.

In this case, the shape of the image 160 output from the pixel group 170 of the image sensor is non-uniform (for example, in the case of an edge pixel), or the intensity of a specific pixel 155 may be different from that of other pixels 155 therein. If different, the pixel is evaluated as bad. The defect may be classified into a defect of the unit array opening 210 and a self defect of the image sensor pixel 155.

In this embodiment, the characteristics of the image sensor 150 are first evaluated before evaluating the characteristics of the arrayed light sources 200 so that the defects of the light sources themselves can be accurately measured. That is, after securing the noise characteristics, the sensitivity characteristics, and the defect characteristics for each pixel 155 of each image sensor 155, the light source 200 may be evaluated in consideration of this.

Accordingly, the evaluation of the image sensor, as shown in Figure 4, the step of evaluating the characteristics of the image sensor (S1), the step of evaluating the light source using the evaluated image sensor (S2) and bad pixels of the image sensor It may be configured to correct the step (S3).

Here, in step S1 of evaluating the characteristics of the image sensor, light is irradiated to each pixel of the image sensor, thereby imaging the light. Thereafter, a pixel deviating from the error range from the average value of the picked-up image (or light quantity) of each pixel 155 is determined as a bad pixel. The bad pixels may be caused by problems such as sensitivity abnormalities, defects, and noises of the actual sensing unit (eg, microlenses, etc.). In addition to the above-described method of evaluating the image sensor, the bad pixels may be detected by various types of image quality evaluation methods.

Evaluating an arrayed light source using the evaluated image sensor (S2) irradiates light corresponding to each pixel group 170 of the image sensor for each unit light source (array opening 210). Then, the image sensor 150 captures an image corresponding to one array light source 210 for each pixel group 170 composed of a plurality of pixels.

In the correcting of the bad pixels of the image sensor (S3), after evaluating the array light source, all the bad pixels outside the error range of the average value of the output image are collected for each image sensor pixel group 170.

Next, the image sensor 150 itself is subtracted from the information of all the bad pixels to detect only the bad pixels of the pure light source itself. Accordingly, more accurate light source evaluation can be performed.

As described in detail above, according to the present invention, an image sensor including an optical system and a plurality of pixels is disposed below the array light source, and the pixels of the image sensors receive light emitted from each of the array light sources. The image evaluates the optical characteristics of the array light source.

In addition, before performing the evaluation of the light source, by first evaluating the performance of the image sensor to exclude the defect of the light source evaluation apparatus, it is possible to detect the characteristics of the pure array light source.

Although the present invention has been described in detail with reference to preferred embodiments, the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. .

1 is a cross-sectional view showing an apparatus for evaluating a light source having a light modulating micro aperture according to an embodiment of the present invention;

FIG. 2 is a plan view of a light source having the light modulation micro apertures of FIG. 1;

3 is a plan view of an image sensor group photographing an image by irradiating light from a unit light source according to an embodiment of the present invention; and

4 is a flowchart illustrating a method of evaluating a light source according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: light source evaluation device 120: optical system

150: image sensor array 200: light source

Claims (7)

A light source comprising a plurality of micro apertures; An image sensor disposed under the light source and receiving and imaging light irradiated from the light source, wherein information of a bad pixel and a normal pixel is detected in the imaging process; And An optical system interposed between the light source and the image sensor to form light irradiated from the light source onto pixels of the image sensor, And the normal pixel of the image sensor is configured to receive and image light emitted from the light source and to evaluate the characteristics of the light source through the intensity and shape of the image. The method of claim 1, The image sensor includes a plurality of image sensor pixel groups consisting of several pixels, And each opening is arranged to correspond to the image sensor pixel group, wherein the one image sensor pixel group receives light irradiated from the one opening and image it. The method of claim 1, The light source is a substrate made of a transparent material; And And a metal thin film formed on the bottom surface of the substrate and including minute openings formed at predetermined intervals. Providing an optical characteristic evaluation device composed of an optical system and an image sensor having a plurality of pixels; Evaluating characteristics of the image sensor to detect self-poor pixels of the optical characteristic evaluation apparatus; Disposing a light source having a plurality of openings on the optical system; And And receiving light irradiated from the light source and evaluating characteristics of the light source in a state in which self-bad pixels of the optical property evaluation apparatus are taken into consideration by an image detected by the image sensor. The method of claim 4, wherein Before evaluating the characteristics of the light source, And evaluating characteristics of the image sensor to detect defective pixels of the optical characteristic evaluation apparatus itself. The method of claim 5, Detecting a bad pixel of the image sensor itself, Imaging an image by irradiating light to each pixel of the image sensor; And And determining the own defective pixel when the captured image of the specific pixel is outside an error range of the average value of the captured image of the surrounding pixel. The method of claim 5, Evaluating the characteristics of the light source, Defining a group of image sensor pixels by grouping the plurality of pixels of the image sensor several times; The one image sensor pixel group receiving light irradiated from the one opening, detecting an image therefor, and detecting a defect from the image; And Subtracting the own defective pixel of the image sensor from the defect to detect a defect of the pure light source.

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